Male Wistar rats weighing 250-300 g were used in all experiments. The rats were allowed access to standard laboratory diet and water ad libitum prior to the experiments, and received care in compliance with international regulations. The National Council Committee from Argentine approved animal protocols.

LMOs were prepared using “free-hand” techniques, by cutting the liver into thin blocks. They were cut using a microtome blade attached to a plastic handle (designed in our laboratory), to facilitate handling. We worked at 0 °C (on ice) to reduce tissue deterioration, and over a paper filter to prevent the slippage of the blocks that could prevent the precise cutting of the sheets. After slicing, LMOs were placed in different solutions. Fresh LMOs (controls) were placed in Krebs-Henseleit Reoxygenation media (KHR) its composition was: 114 mM NaCl, 25 mM NaHCO3, 4.8 mM KCl, 1.5 mM CaCl2, 10 mM hepes, 25 mM glucose, 1 mM allopurinol, 3 mM glycine; pH = 7.40, 310 mOsm/kg water. LMOs that underwent the preservation process were placed in the different preservation solutions, whose compositions are detailed below.

Before starting with the preservation experiments, and in order to validate the recently described cutting technique, LMOs thickness was determined, and then they were incubated (37 °C, KHR, 120 min) to measure the Total Water Content (TWC), Extra and Intracellular Water Space, and K+ and Na+ content. LMOs architectural integrity was assessed by histological analysis.

Once cut, LMOs were placed in the different solutions. Approximately 50 LMOs were stored for up to 48 h at 0 °C in a glass Boeco bottle containing 50 mL of the following preservation solutions:

• a)

  ViaSpan® (UW Bristol-Myers-Squibb, Bruxelles, Belgium).

• b)

  BGS.

• c)

  BG plus 4% PEG 8 kDa (BG8).

• d)

  BG plus 4% PEG 20 kDa (BG20).

• e)

  BG plus 4% PEG 35 kDa (BG35) (Table 1).

  Table 1.

  Composition of the preservation solutions ViaSpan®, BGS, BG8, BG20 and BG35.

  	ViaSpan®	BGS	BG 8	BG20	BG35
  Impermeants (mM)
  Lactobionate	100
  Gluconate		100	100	100	100
  Raffinose	30
  Sucrose		40
  Buffers (mM)
  kh2po4	25	2.5	2.5	2.5	2.5
  BES		70	50	50	50
  Substrates (mM)
  Allopurinol	1	1	1	1	1
  Glutathione	3	3	3	3	3
  Adenosine	5	5	5	5	5
  Glycine		15	15	15	15
  Colloids (g/L)
  HES	50
  PEG 8 kDa			40	40	40
  PEG 20 kDa			40	40	40
  PEG 35 kDa			40	40	40
  pH 7.40	7.40	7.40	7.40	7.40
  Osm (mOsm/kgwater)	320 ± 4	326 ± 5	331 ± 3	335 ± 6	339 ± 4

  To adapt the BGS solution to LMOs preservation, its composition was modified. The sucrose was replaced by PEG and the concentration of the buffer agent BES was diminished. The different solutions only vary in the MW of the PEG they contain. All the solutions were bubbled with 100% N2 for 45 min at 0 °C before use. BES: [N, N-bis (2-hydroxyethyl)-2-aminoethanesulfonic acid]. HES: Hydroxyethyl starch. PEG: Polyethyleneglycol. Dexamethasone 16 mg/L, insulin 40 UI/L and penicillin G 200.000 UI/L were added to Viaspan® before use. Streptomycin 250 mg/mL and penicillin G 10.000 UI/L were added to BGS, BG8, BG20 and BG35 before use.

48 h cold storage were chosen because in preliminary experiments (data not shown) the viability evaluated by Lactate Dehydrogenase (LDH) Release was only moderately altered by 24 h of cold ischemia, but a clear cut difference after 48 h was seen.

A sample was removed daily from all the preserved groups, in order to estimate the time course changes in viability (see Viability parameters and functional assays).

After 48 h of cold storage, LMOs were washed thoroughly with a rinse solution previously described by our group18 to remove residual preservation solution that could interfere during the subsequent reoxygenation. This step was carried out at 37°C during 120 min in a Dubnoff metabolic shaker in KHR under carbogen atmosphere (95%O2:5% CO2) in 6- wells culture plates. Two LMOs with 5 mL of KHR were placed in each well.

First, the BGS composition was modified to adapt it to LMOs preservation. The main modifications involved the addition of PEG of different MW (8, 20 and 35 kDa), the remotion of sucrose, and the decrease on BES concentration (from 70 mM to 50 mM). As it was already stated, one of the key components of BGS solution is the buffer agent BES, a suitable buffering agent to avoid preservation-related changes in the intracellular pH.8 So the aim of part I of this paper was the determination of the buffering capacity of the developed preservation solutions, and the evolution of pH of these solutions during the cold storage of LMOs.

Part II was meant to evaluate the effects that the changes introduced to BGS, especially the PEG addition, have on the total water content, and the viability and functionality of LMOs. During the preservation period, we have evaluated LDH Release and Total Water Content. To distinguish between tissue responses displayed during the cooling step, and those caused by cold storage but exposed during the reoxygenation process, we have also assessed LDH Release, Total Water Content, Glycogen Content, Oxygen Consumption and Histological Characteristics of the preserved LMOs during reoxygenation. Freshly cut LMOs were used as controls.

• •

  Determination of the Buffering Capacity of the preservation solutions: The buffering capacity of a preservation solution is defined as the concentration of H+ needed to produce a decline of 1 pH unit from the initial pH of the solution.19 Each tested solution was titrated with 0.1 M HCl under continuous stirring and the pH was continuously measured at 0 °C and plotted out.

• •

  Time course evolution of preservation solution pH during cold storage of LMOs.The preservation solutions pH changes were measured at 0 °C using a pH-meter (JENCO, MODEL 6071) after 24 and 48 h of cold storage.

• •

  Thickness. LMOs thickness was determined using a gauge DIGIMESS® (Pocket Thickness Gage, 0.1 mm-10 mm). Sections were placed between two coverslips and the thickness was measured; the thickness of the two coverslips was previously measured and substracted to obtain the LMO thickness.

• •

  TWC. Tissue water content was determined by a dessication method (12 h in a hot oven at 105 °C). TWC was expressed as mL water/g dry tissue and performed in quadruplicated for each experiment to produce a mean value.

• •

  Extra and Intracellular Water Space. LMOs were incubated (in triplicate) for 120 minutes in KHR containing the extracellular volume marker inulin (4 mg/mL). After 60 and 120 min of incubation the sections were dried, weighed and homogenized to determine the inulin space. The tissue and medium inulin concentration were determined using Roe assay.20 The volumes of extra and intracellular compartments were obtained from the distribution volume of the extracellular tracer inulin. Extracellular Water Space was expressed as mL extracellular water/mL total water and Intracellular Water Space as mL intracellular water/ mL total water. They were performed in quadruplicated for each experiment to produce a mean value.

• •

  Tissue K+ and Na+ content. Each dry tissue was dissolved in HNO3 (1mM) overnight to determinate Na+ and K+ levels by flame photometry. Na+ and K+ levels were expressed as μEq/ g dry tissue.

• •

  Viability parameters and functional assays

• •

  LDH Release. The LDH activity was measured in the incubation medium and in the tissue as described previously.21 Results were expressed as the percentage of the total enzyme activity released to the incubation medium.

• •

  Glycogen Content. The glycogen content of LMOs was determined using the Carr and Neff’s assay.22 Two LMOs were removed from the incubation medium and were stored at -20 °C until the colorimetric determination was made. The glycogen content was expressed as mg glycogen/g tissue.

• •

  Oxygen Consumption. Fresh (controls) and cold stored LMOs were incubated in KHR medium at 37 °C in a Dubnoff metabolic bath under carbogen atmosphere with continuous shaking for 120 min. At different times two LMOs were added to a thermostatized oxygen electrode chamber designed in our laboratory. The chamber contains 10.5 mL of respiration medium (Krebs-Henseleit media with 10 mM hepes and 2 mM pyruvate, pH = 7.40 at 36 °C). The oxygen content of this respiration medium equilibrated with air was determined according to Robinson23 and found to be 0.524 ± 0.024 μmol/mL at 36 °C and at a barometric pressure of 760 mmHg, n = 10. Oxygen consumption was measured using a Clark-type oxygen electrode (YSI 5300, Yellow Spring, OH, USA). The endogenous respiration rate was assessed after a stabilization period of 2 min. The rate of oxygen uptake was recorded and calculated over a 5 min period. Results were expressed as pmol O2/min/g tissue.

The efficacy of the different preservation solutions in conserving LMOs morphology after cold preservation and normothermic reoxygenation was evaluated. Samples of all the experimental groups were fixed in 10 % formaldehyde in PBS (pH = 7.40) and histologically processed for paraffin embedding. Slices of 5 μm thick were cut and stained with hematoxilin & eosin. Afterward, they were analyzed with a light field microscopy (Olympus Co, LTD. Model U-MDOB, 20X objectives, equipped with a digital camera Olympus model D-360 Zoom-3.2 megapixels of resolution) taking into account hepatocyte cords integrity, presence of vacuoles, blebs or necrotic focus, sinusoidal endothelial cells shape, and the general morphological aspect of the hepatic lobules.

Statistical differences between values were assessed by analysis of variance (ANOVA) followed by Scheffe’s multiple range test. A p value less than 0.05 was considered statistically significant.

Although LMOs were manually cut, thin and homogeneous cuts were obtained. The LMOs average thickness was 436 ± 18 μm, n = 50.

Table 1 shows TWC, Extra and Intracellular Water Space, and Na+ and K+ content (37 °C-120 min-KHR) of LMOs freshly cutted, n = 20.

The TWC value (mL water/g dry tissue) at the beginning of the incubation was 3.74 ± 0.32 and no significant differences were observed after 60 and 120 min (3.72 ± 0.32 and 3.69 ± 0.22, respectively).

The Extra and Intracellular Water Spaces did not change after 120 min of incubation. Extracellular water values (mL extracellular water/mL total water) were: 0.37 ± 0.03 after 60 min and 0.43 ± 0.02 after 120 min; whereas the values obtained for the Intracellular Water Space (mL extracellular water/mL total water) were 0.62 ± 0.03 after 60 min and 0.57 ± 0.02 at 120 min.

The LMOs also maintained the intracellular Na+ and K+ contents after 120 min of reoxygenation. The tissue K+ content values were 88 ± 22 and 64 ± 23 μEq K+/g dry tissue, and the Na+ levels were 572 ± 94 and 637 ± 89 μEq Na+/g dry tissue, after 60 and 120 min.

Potentiometric titration curves were generated for each solution by adding small amounts of HCl 0.1 N to the solution of interest. As illustrated in Figure 1A, BG8, BG20 and BG35 showed a substantially greater buffering capacity than ViaSpan®. The buffering capacity expressed as mEq H+/L/pH unit obtained for BG8 was 37.2 ± 1.2; 38.5 ± 1.3 for BG20; 36.1 ± 0.8 for BG35 and 11.3 ± 0.9 for ViaSpan®. No differences were observed between BG8, BG20 and BG35.

Figure 1B shows the time course evolution of the preservation solution pH from LMOs cold stored in BG8, BG20, BG35 and ViaSpan®. No significant differences on the pH were found after 48 h of cold storage in BG8, BG20 and BG35. However, pH of the LMOs preserved in ViaSpan® showed a statistical increase (p < 0.05) after 48 h of preservation (from 7.68 ± 0.03 at time 0 until 7.87 ± 0.04 at 48 h, n = 3). This value was also different to that observed in LMOs stored in BG8 (7.55 ± 0.04); BG20 (7.51 ± 0.04) and BG35 (7.39 ± 0.07) (p < 0.05, n = 5).

Figure 1. A..

Determination of the buffering capacity of BG8, BG20, BG35 and ViaSpan® solutions. Each tested solution was titrated with 0.1 M HCl, and the pH was measured at 0 °C sequentially and plotted out. Data are expressed as mean ± SD for 4 determinations. * different from BG8, BG20 and BG35, p < 0.05. B. Evolution of preservation solution pH of LMOs cold stored in BG8, BG20, BG35 and ViaSpan® solutions during 48 h at 0 °C. Each point is expressed as mean ± SD for 3 LMOs preparations.* different from pH = 7.40 and from BG8, BG20 and BG35, p < 0.05.

(0.08MB).

An increase in LDH Release during cold storage for all the evaluated solutions was observed (Figure 2A). However, the LDH Release for LMOs preserved in BGS was significantly higher than the values obtained for all the others groups. After 48 h, LDH Release was 50.3 ± 3.7 % for LMOs preserved in BGS solution whereas for LMOs preserved in the other solutions this parameter was statistically minor (p < 0.05, n = 5): 25.7% ± 2.6 for BG8, 20.2% ± 3.1 for BG20, 18.9% ± 2.9 for BG35 and 21.2% ± 1.7 for ViaSpan®.

Figure 2. A..

Time course LDH Release of LMOs preserved in BGS, BG8, BG20 BG35 and ViaSpan® solutions during cold preservation (48 h at 0 °C). Data are expressed as mean ± SD for 4 HMOs preparations. * different from all the other groups, p > 0.05. B. Time course of Water Content of LMOs preserved in BGS, BG8, BG20, BG35 and ViaSpan® solutions. Data are expressed as mean ± SD for 4 LMOs preparations. * Different from all the other groups. * different from the initial preservation time (t = 0), p < 0.05.

(0.09MB).

Figure 2B shows the TWC evolution for LMOs during the cold storage in the different preservation solutions. For LMOs preserved in BGS, the TWC was significantly higher (p < 0.05, n = 5) than for LMOs preserved in the others solutions. After 48 h, the BGS group contained 3.6 ± 0.4 mL water/g dry tissue, against 1.8 ± 0.4 for BG8, 2.1 ± 0.3 for BG20, 2.3 ± 0.2 for BG35 and 2.5 ± 0.3 for ViaSpan®. In addition, only for LMOs cold stored in BGS solution we found a significant increase in TWC with an increased preservation time (from 2.8 ± 0.4 at t = 0 until 3.6 ± 0.6 after 48 h). Due to these results, we decided not to evaluate this group during the reoxygenation period.

After 120 min of rewarming, no statistically significant differences were found neither in LDH Release (Figure 3A) nor in TWC (Figure 3B) between fresh LMOs (controls) and LMOs preserved in BG8, BG20, BG35 and ViaSpan®. After 120 min LDH Release (%) was: 30.4 ± 6.8 for control, 30.2 ± 4.9 for BG8, 29.4 ± 6.5 for BG20, 23.4 ± 3.4 for BG35 and 35.4 ± 5.5 for ViaSpan® (n = 5). Figure 3C shows the TWC of controls and LMOs cold preserved in the different solutions. At the beginning of the rewarming, controls showed a TWC significantly higher than the LMOs preserved in the different solutions analyzed (3.72 ± 0.32 for control, 3.00 ± 0.08 for BG8, 2.73 ± 0.09 for BG20, 2.90 ± 0.18 for BG35 and 3.10 ± 0.37 for ViaSpan®, n = 5, p < 0.05). However, after 60 and 120 min no significant differences were observed, indicating that all the LMOs from the preserved groups can regulate the TWC. Figure 3C shows the Glycogen Content and the Oxygen Consumption during the reoxygenation step. At the beginning (time 0), only LMOs preserved in ViaSpan® showed a glycogen content significantly smaller than the rest of the studied group (p < 0.05, n = 5). The values, expressed as mg glycogen/g tissue were: 27.50 ± 1.40 for controls, 21.70 ± 1.70 for BG8, 27.70 ± 5.60 for BG20, 25.60 ± 2.60 for BG35 and 13.70 ± 2.00 for ViaSpan®. A significant reduction of the glycogen content as the reoxygenation time increase was observed for all the analyzed groups (p < 0.05, n = 5). However, only LMOs from BG20 and BG35 groups showed a glycogen content similar to controls (18.83 ± 4.70 for controls; 18.04 ± 1.45 for BG20 and 19.51 ± 2.45 for BG35, 9.95 ± 1.70 for BG8 and 10.50 ± 1.40 for ViaSpan®). It is important to note that while LMOs preserved in Viaspan® showed smaller glycogen contents than the others groups at the beginning of the reoxygenation, the percentage of loss at the end of this step was similar (24 ± 2.1) to those obtained for BG20 (30 ± 1.6), BG35 (26 ± 1.4) and controls (29 ± 2.2). The group that showed the greatest decrease was BG8 with 54± 2.7 of loss at 120 min. Panel D of Figure 3 shows Oxygen Consumption of controls and preserved LMOs during reoxigenation. After 120 min only LMOs preserved in BG35 showed values of Oxygen Consumption (expressed as pmoles O2/g tissue/min) similar to controls (0.85 ± 0.11 for BG35 and 0.96 ± 0.16 for controls). On the other hand, LMOs preserved in BG8, BG20 and ViaSpan® showed oxygen consumption rates significantly smaller than controls (0.51 ± 0.09 for BG8, 0.58 ± 0.17 for BG20, 0.51 ± 0.19 for ViaSpan®).

Figure 3. A..

Time course of LDH Release after 120 min of reoxygenation determined in fresh LMOs and cold preserved in BG8, BG20, BG35 and ViaSpan® solutions. Data are expressed as mean ± SD for 5 LMOs preparations. # different from time 0, p < 0.05. B. Time course of Total Water Content during 120 min of reoxygenation determined in fresh LMOs and cold preserved 48 h in BG8, BG20, BG35 and ViaSpan® solutions. Each bar represents the mean ± SD for 5 LMOs preparations. * different from all the other groups, p < 0.05. C. Time course of Cellular Glycogen Content after 120 min of reoxygenation determined in fresh LMOs and cold preserved in BG8, BG20, BG35 and ViaSpan® solutions. Data are expressed as mean ± SD for 5 LMOs preparations. $ different from LMOs preserved in BG20 and BG35 solutions; & different from controls, p < 0.05. D. Time course of Oxygen Consumption in fresh LMOs and cold preserved in BG8, BG20, BG35 and ViaSpan® solutions. Each bar represents the mean ± SD for 5 LMOs preparations. ¤ different of LMOs preserved in BG20, BG35 and controls; & different from controls, p < 0.05.

(0.16MB).

LMOs from control and preserved groups (BG 8, BG 20, BG 35 and ViaSpan®, 48 h at 0 °C, followed by normothermic reoxygenation) were analyzed.

Control group showed conserved hepatocyte cords architecture with endothelial cells attached to the perisinusoidal matrix. The shape of these cells was normal and the hepatic lobules preserved their architecture at the end of the reoxygenation period (Figure 4). At the beginning of the reoxygenation time, LMOs preserved in BG 8, BG 20, BG 35 and ViaSpan® showed good hepatocyte cord integrity with a grater calibre compared with controls, and a mixed population of endothelial cells: ones swollen and attached to the perisinusoidal matrix and others swollen but detached and inside the sinusoidal lumen (data not shown). After 120 min of reoxygenation all the preserved groups showed conserved hepatocyte cord integrity with sinusoides markedly opened. Most of the endothelial cells were swollen and inside the sinusoidal lumen. ViaSpan® solution presented the grater amount of swollen hapatocytes together with some blebs, and BG8 showed an apparently conserve parenchyma. However, hepatocyte cords and sinusoids were not clearly distinguished.

Figure 4.

LMOs morphology. Samples were taken from control and preserved groups at the end (t= 120 min) of the normother-mic reoxygenation period. Control: normal morphology through the hepatic parenchyma surrounding a central vein (CV). LMOs preserved in BG20, LMOs preserved in BG35 and LMOs preserved in ViaSpan®: all groups presented opened sinusoids (S); swollen hepatocytes (H); rounded (arrow heads) and fusiform (arrows) endothelial cells. ViaSpan® presented blebs (B) and the gratest amount of swollen hepatocytes (H). LMOs preserved in BG8 apparently conserved the architecture of the hepatic lobule; nonetheless, hepatocyte cords and sinusoid were poorly distinguished. Magnifications 20X.

(0.24MB).